Abstract
Plant-pollinator interactions have been suggested as key drivers of morphological divergence and speciation of the involved taxa. These interactions can also promote sexual dimorphism in both the plant and pollinator, particularly if the pollinator is also a seed-eater and/or exerts different selection pressures on male and female plants. Here we tested the hypotheses that plant-pollinator interactions can be reflected in trait variation and sexual dimorphism in both organisms within and across populations. Across nine European populations, we examined intraspecific variation and sexual dimorphism in phenotypic traits potentially involved in the plant–insect interaction of the dioecious white campion Silene latifolia (Caryophyllaceae) and its specialist pollinator Hadena bicruris (Noctuidae). This interaction is expected to entail sex-specific selective pressures, as female moths lay eggs on female plants and the larvae predate on the seeds during their development. We compared divergence in phenotypic traits among populations and between sexes within populations, examined correlations between plant and pollinator traits, and between phenotypic distances and genetic distances among co-occurring populations for both plants and insects. We found key differences in phenotypic traits across populations of both the plant and moth, though only in the moth were these differences correlated with geographic distances. We also found evidence for sexual dimorphism in the plant but not in the pollinator. Evolution of floral sexual dimorphism in S. latifolia most likely results from the joint contribution of different selective forces, including biotic interactions with H. bicruris moths.
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Alexander HM (1989) An experimental field study of anther-smut disease of Silene alba caused by Ustilago violacea: genotypic variation and disease incidence. Evolution 43:835–847
Alexander HM, Antonovics J (1988) Disease spread and population dynamics of anther-smut infection of Silene alba caused by the fungus Ustilago violacea. J Ecol 76:91–104
Anderson B, Johnson SD (2008) The geographical mosaic of coevolution in a plant-pollinator mutualism. Evolution 62:220–225
Anderson B, Alexandersso R, Johnson SD (2009) Evolution and coexistence of pollination ecotypes in an African Gladiolus Iridaceae. Evolution 64:960–972
Anderson B, Terblanche JS, Ellis AG (2010) Predictable patterns of trait mismatches between interacting plants and insects. BMC Evol Biol 10:204
Anstett MC, Hossaert-McKey M, Kjellberg F (1997) Figs and fig-pollinators: coevolutionary conflicts in a coevolved mutualism. Trends Ecol Evol 12:94–99
Antonovics J, Alexander HM (1992) Epidemiology of anther-smut infection of Silene alba (=S. latifolia) caused by Ustilago violacea: patterns of spore deposition in experimental populations. Proc R Soc B 250:157–163
Avilés JM, Vikan JR, Fossøy F et al (2012) Egg phenotype matching by cuckoos in relation to discrimination by hosts and climatic conditions. Proc R Soc B 279:1471–2954
Bernasconi G, Antonovics J, Biere A et al (2009) Silene as a model system in ecology and evolution. Heredity 103:5–14
Biere A (2002) A plant pathogen reduces the enemy-free space of an insect herbivore on a shared host plant. Proc R Soc B 269:2197–2204
Bopp S, Gottsberger G (2004) Importance of Silene latifolia ssp alba and S. dioica Caryphyllacea as host plants of the parasitic pollinator Hadena bicrusis Lepidoptera, Noctuidae. Oikos 105:221–228
Bucheli E, Shykoff JA (1999) The influence of plant spacing on density-dependent versus frequency-dependent spore transmission of the anther smut Microbotryum violaceum. Oecologia 119:55–62
Burkhardt A et al (2009) Benefits and costs to pollinating, seed-eating insects: the effect of flower size and fruit abortion on larval performance. Oecologia 161:87–98
Burkhardt A, Ridenhour BJ, Delph LF, Bernasconi G (2012) The contribution of a pollinating seed predator to selection on Silene latifolia females. J Evol Biol 25:461–472
Castillo DM, Kula AA, Fenster KA et al (2013) Specialist pollinating seed predator exhibits oviposition strategy consistent with optimal oviposition theory. Ecol Entomol 38:164–172
Cook JM, Rasplus JY (2003) Mutualists with attitude: coevolving fig wasps and figs. Trends Ecol Evol 18:241–248
Delph LF (2007) The genetic integration of sexually dimorphic traits in the dioecious plant, Silene latifolia. In: Fairbairn DJ, Blanckenhorn WU, Szekely T (eds) Sex, size and gender roles: evolutionary studies of sexual size dimorphism. Oxford University Press, New York, pp 115–123
Delph LF, Bell DL (2008) A test of the differential-plasticity hypothesis for variation in the degree of sexual dimorphism in Silene latifolia. Evol Ecol Res 10:61–75
Delph LF, Meagher TR (1995) Sexual dimorphism masks life-history trade-offs in the dioecious plant Silene latifolia. Ecology 76:775–785
Delph LF, Knapczyk FN, Taylor DR (2002) Among-population variation and correlations in sexually dimorphic traits of Silene latifolia. J Evol Biol 15:1011–1020
Delph LF, Gehring JL, Frey FM et al (2004) Genetic constraints on floral evolution in a sexually dimorphic plant revealed by artificial selection. Evolution 58:1936–1946
Delph LF, Arntz AM, Scotti-Saintagne C et al (2010) Quantitative trait loci and genomic architecture of sexual dimorphism in the dioecious plant Silene latifolia. Evolution 64:2873–2886
Dötterl S, Jürgens A (2005) Spatial fragrance patterns in flowers of Silene latifolia: lilac compounds as olfactory nectar guides? Plant Syst Evol 255:99–109
Dufaÿ M, Anstett MC (2003) Confliscts between plants and pollinators that reproduce within influorescences: evolutionary variations on a theme. Oikos 100:3–14
Elmqvist T, Liu D, Carlsson U et al (1993) Anther-smut infection in Silene dioica: variation in floral morphology and patterns of spore deposition. Oikos 207–216
Elzinga JA, Bernasconi G (2009) Enhanced frugivory on invasive Silene latifolia in its native range due to increased oviposition. J Ecol 97:1010–1019
Elzinga JA, Biere A, Harvey JA (2002) The rearing of the gregarious koinobiont endoparasitoid Microplitis tristis Hymenoptera: braconidae on its natural host Hadena bicruris Lepidoptera: Noctuidae. Proc Sect Exp Appl Entomol Netherlands Entomol Soc 13:109–115
Elzinga JA, Turin H, van Damme JM et al (2005) Plant population size and isolation affect herbivory of Silene latifolia by the specialist herbivore Hadena bicruris and parasitism of the herbivore by parasitoids. Oecologia 144:416–426
Excoffier L, Estoup A, Cornuet JM (2005) Bayesian analysis of an admixture model with mutations and arbitrarily linked markers. Genetics 169:1727–1738
Fraley C, Raftery AE, Murphy TB, Scrucca L (2012) Mclust Version 4 for R: normal mixture modeling for model-based clustering, classification, and density estimation. Technical report no. 597, Department of Statistics, University of Washington
Golonka A, Vilgalys R (2013) Nectar inhabiting yeasts in Virginian populations of Silene latifolia (Caryophyllaceae) and co flowering species. Am Midl Nat 169:235–258
Goulson D, Jerrim K (1997) Maintenance of the species boundary between Silene dioica and S. latifolia red and white campion. Oikos 79:115–126
Hathaway L, Andersson S, Prentice HC (2009) Experimental crosses within European Silene latifolia Caryophyllaceae: intraspecific differentiation, distance effects, and sex ratio. Botany 87:231–240
Holland JN, DeAngelis DL, Schultz ST (2004) Evolutionary stability of mutualism: interspecific population regulation as an ESS. Proc R Soc B 271:1807–1814
Janzen DH (1980) When is it coevolution? Evolution 34:611–612
Jennersten O (1983) Butterfly visitors as vectors of Ustilago violacea spores between caryophyllaceous plants. Oikos 40:125–130
Jolivet C, Bernasconi G (2006) Experimental analysis of constitutive and induced defense in a plant-seed-predator system. Funct Ecol 20:966–972
Kephart S, Reynolds RJ, Rutter MT et al (2006) Pollination and seed predation on Silene and allied Caryophyllaceae: evaluating a model system to study the evolution of mutualisms. New Phytol 169:667–680
Kula AA, Dudash MR, Fenster CB (2013) Choices and consequences of oviposition by a pollinating seed predator, Hadena ectypa (Noctuidae), on its host plant, Silene stellata (Caryophyllaceae). Am J Bot 100:1148–1154
Labouche AM, Bernasconi G (2010) Male moths provide mutualistic benefits in the Silene latifolia–Hadena bicruris pollination, seed predation system. Funct Ecol 24:534–544
Labouche AM, Bernasconi G (2013) Cost limitation through constrained oviposition site in a plant-pollinator/seed predator mutualism. Funct Ecol 27:509–521
Magalhaes IS, Gleiser G, Labouche A et al (2011) Comparative population genetic structure in a plant-pollinator/seed predator system. Mol Ecol 20:4618–4630
Meagher TR (1994) The quantitative genetics of sexual dimorphism in Silene latifolia (Caryophyllaceae). 2. Response to sex-specific selection. Evolution 48:939–951
Nuismer SL, Gomulkiewicz R, Ridenhour BJ (2010) When is correlation coevolution? Am Nat 175:525–537
Pellmyr O (2003) Yuccas, Yucca Moths, and coevolution: a review. Ann Missouri Bot Gard 90:35–55
Pettersson MW (1991) Flower herbivory and seed predation in Silene vulgaris Caryophyllaceae: effects of pollination and phenology. Holarct Ecol 14:45–50
Pujol B, Wilson AJ, Ross RIC et al (2008) Are QST–FST comparisons for natural populations meaningful? Mol Ecol 17:4782–4785
Richards CM, Emery SN, McCauley DE (2003) Genetic and demographic dynamics of small populations of Silene latifolia. Heredity 90:181–186
Roche BM, Alexander HM, Maltby AD (1995) Dispersal and disease gradients of anther-smut infection of Silene alba at different life stages. Ecology 76:1863–1871
Scheiner SM, Gurevitch J (2001) Design and analysis of ecological experiments. Oxford University Press, Oxford
Shykoff JA, Bucheli E (1995) Pollinator visitation patterns, floral rewards and the probability of transmission of Microbotryum violaceum, a venereal disease of plants. J Ecol 83:189–198
Steven JC (2007) Sexual dimorphism in the quantitative-genetic architecture of floral, leaf, and allocation traits in Silene latifolia. Evolution 61:42–57
Thompson JN (1994) The coevolutionary process. Chicago University Press, Chicago
Thompson JN (2005) The geographic mosaic of coevolution. Chicago University Press, Chicago
Witt T, Jürgens A, Geyer R, Gottsberger G (1999) Nectar dynamics and sugar composition in flowers of Silene and Saponaria species Caryophyllaceae. Plant Biol 1:334–345
Wolfe LM (2002) Why alien invaders succeed: support for the escape-from-enemy hypothesis. Am Nat 160:705–711
Wright JW, Meagher TR (2004) Selection on floral characters in natural Spanish populations of Silene latifolia. J Evol Biol 17:382–395
Yu Q, Ellen ED, Wade MJ, Delph LF (2011) Genetic differences among populations in sexual dimorphism: evidence for selection on males in a dioecious plant. J Evol Biol 24:1120–1127
Acknowledgments
We thank Anne-Marie Labouche, David Nash, Nat Holland, Mario Vallejo-Marin and the referees for valuable discussion and for comments on the manuscript. We thank Gabriela Gleiser for the genetic data, Anne-Marie Labouche for the phenotypic data, Ladislaus Reser (Naturhistorisches Museum Luzern) for insect identification, Luca Scrucca for advice on the Mclust analyses, Dessislava Savova-Bianchi for practical help in the laboratoy, Arjen Biere, Gösta Börjeson, Stefan Dötterl, Simon Laegaard, Honor Prentice, Per Toräng and Torbjörn Tyler for help and logistical support with field sampling, and Daniel Cherix for advice. This study was supported by the Swiss National Science Foundation (Grant No. 3100A0_122004/1 to GB).
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Magalhaes, I.S., Bernasconi, G. Phenotypic divergence and inter-specific trait correlation in a plant-pollinator/seed predator mutualism. Evol Ecol 28, 905–922 (2014). https://doi.org/10.1007/s10682-014-9713-z
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DOI: https://doi.org/10.1007/s10682-014-9713-z